In answer to a question on Cross Validated, I wrote a simple function that used arbitrary quantile functions as its arguments

```
etacor=function(rho=0,nsim=1e4,fx=qnorm,fy=qnorm){
#generate a bivariate correlated normal sample
x1=rnorm(nsim);x2=rnorm(nsim)
if (length(rho)==1){
y=pnorm(cbind(x1,rho*x1+sqrt((1-rho^2))*x2))
return(cor(fx(y[,1]),fy(y[,2])))
}
coeur=rho
rho2=sqrt(1-rho^2)
for (t in 1:length(rho)){
y=pnorm(cbind(x1,rho[t]*x1+rho2[t]*x2))
coeur[t]=cor(fx(y[,1]),fy(y[,2]))}
return(coeur)
}
```

However, both `fx`

and `fy`

may require their own parameters. For instance, when `fx=qchisq`

or when `fy=qgamma`

. As a default solution, in my implementation, I used

`fx=function(x) qchisq(x,df=3)`

and

`fy=function(x) qgamma(x,scale=.2)`

but this is quite time consuming.

For instance,

```
> rhos=seq(-1,1,.01)
> system.time(trancor<-etacor(rho=rhos,fx=qlnorm,fy=qexp))
utilisateur système écoulé
0.834 0.001 0.834
```

versus

```
> system.time(trancor<-etacor(rho=rhos,fx=qlnorm,fy=function(x) qchisq(x,df=3)))
utilisateur système écoulé
8.673 0.006 8.675
```

`...`

syntax: cran.r-project.org/doc/manuals/r-release/…`df.x`

and`df.y`

in your`...`

for`etacor`

, (2) parsing`...`

to grab these and (3) passing the parsed-out values (if any are found) to`fx`

and`fy`

. It's complicated, but that shouldn't be too surprising.`fx`

and`fy`

, and then in the function you'd call them via`do.call`

with a constructed list of arguments.`qexp`

is going to take the same amount of time as evaluating`qchisq`

.`x<-runif(1000); microbenchmark::microbenchmark(qexp(x),(function(x){qexp(x)})(x), qchisq(x, 3), (function(x){qchisq(x, 3)})(x))`

. It's not the`function()`

part that's slowing things down, it's that you're using a more complicated distribution.3more comments